Justin Legleiter scite author profile

Many proteins suspected of causing neurodegenerative diseases exist in diverse assembly states. For most, it is unclear whether shifts from one state to another would be helpful or harmful. We used mutagenesis to change the assembly state of Alzheimer disease (AD)-associated amyloid-␤ (A␤) peptides. In vitro, the "Arctic" mutation (A␤E22G) accelerated A␤ fibrillization but decreased the abundance of nonfibrillar A␤ assemblies, compared with wild-type A␤. In human amyloid precursor protein (hAPP) transgenic mice carrying mutations adjacent to A␤ that increase A␤ production, addition of the Arctic mutation markedly enhanced the formation of neuritic amyloid plaques but reduced the relative abundance of a specific nonfibrillar A␤ assembly (A␤*56). Mice overexpressing Arctic mutant or wildtype A␤ had similar behavioral and neuronal deficits when they were matched for A␤*56 levels but had vastly different plaque loads. Thus, A␤*56 is a likelier determinant of functional deficits in hAPP mice than fibrillar A␤ deposits. Therapeutic interventions that reduce A␤ fibrils at the cost of augmenting nonfibrillar A␤ assemblies could be harmful. Alzheimer disease (AD)3 and many other neurodegenerative disorders are associated with the accumulation of abnormal protein assemblies in the central nervous system (CNS). Much evidence suggests that this association reflects a causal relationship in which the abnormal proteins actually trigger the neuronal dysfunction and degeneration that characterize these conditions (1-3). The prevalence of AD and other neurodegenerative proteinopathies is increasing rapidly around the world, most likely because of their age dependence, the increasing longevity of many populations, and the lack of effective strategies for treatment and prevention (4 -6). This alarming trend underlines the need to better understand the relationship between the accumulation of abnormal proteins in the CNS and the decline of neurological function.This relationship has been difficult to analyze in depth because proteins associated with neurodegenerative disorders can exist in diverse assembly states, and distinct assemblies can differ markedly in pathogenic potential. For example, the amyloid-␤ (A␤) peptide, which seems to play a causal role in AD, can exist as monomers, low molecular weight oligomers (such as dimers and trimers), larger globular oligomers (such as A␤*56, A␤-derived diffusible ligands, amylospheroids, and globulomers), amyloid pores, protofibrils, fibrils, and amyloid plaques that contain densely packed A␤ fibrils and a large number of other molecules and cellular elements (7-15). Which of these structures contributes most critically to neurological decline in AD is a matter of active study and debate that has important implications for therapeutic interventions. Studies of transgenic mice with neuronal expression of human amyloid precursor proteins (hAPP), from which A␤ is released by proteolytic cleavage, suggest that nonfibrillar A␤ assemblies are more critical than amyloid plaques in the pathogene...

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Structure of Gel Phase DMPC Determined by X-Ray Diffraction

Tristram-Nagle

Liu

Legleiter

et al. 2002

Biophysical Journal

335

338

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The structure of fully hydrated gel phase dimyristoylphosphatidylcholine lipid bilayers was obtained at 10 degrees C. Oriented lipid multilayers were used to obtain high signal-to-noise intensity data. The chain tilt angle and an estimate of the methylene electron density were obtained from wide angle reflections. The chain tilt angle is measured to be 32.3 +/- 0.6 degrees near full hydration, and it does not change as the sample is mildly dehydrated from a repeat spacing of D = 59.9 A to D = 56.5 A. Low angle diffraction peaks were obtained up to the tenth order for 17 samples with variable D and prepared by three different methods with different geometries. In addition to the usual Fourier reconstructions of the electron density profiles, model electron density profiles were fit to all the low angle data simultaneously while constraining the model to include the wide-angle data and the measured lipid volume. Results are obtained for area/lipid (A = 47.2 +/- 0.5 A(2)), the compressibility modulus (K(A) = 500 +/- 100 dyn/cm), various thicknesses, such as the hydrocarbon thickness (2D(C) = 30.3 +/- 0.2 A), and the head-to-head spacing (D(HH) = 40.1 +/- 0.1 A).

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ABCA1 Is Required for Normal Central Nervous System ApoE Levels and for Lipidation of Astrocyte-secreted apoE

Wahrle¹,

Jiang²,

Parsadanian³

et al. 2004

Journal of Biological Chemistry

405

357

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ABCA1 is an ATP-binding cassette protein that transports cellular cholesterol and phospholipids onto high density lipoproteins (HDL) in plasma. Lack of ABCA1 in humans and mice causes abnormal lipidation and increased catabolism of HDL, resulting in very low plasma apoA-I, apoA-II, and HDL. Herein, we have used Abca1 ؊/؊ mice to ask whether ABCA1 is involved in lipidation of HDL in the central nervous system (CNS). ApoE is the most abundant CNS apolipoprotein and is present in HDL-like lipoproteins in CSF. We found that Abca1 ؊/؊ mice have greatly decreased apoE levels in both the cortex (80% reduction) and the CSF (98% reduction). CSF from Abca1 ؊/؊ mice had significantly reduced cholesterol as well as small apoE-containing lipoproteins, suggesting abnormal lipidation of apoE. Astrocytes, the primary producer of CNS apoE, were cultured from Abca1 ؉/؉ , ؉/؊ , and ؊/؊ mice, and nascent lipoprotein particles were collected. Abca1 ؊/؊ astrocytes secreted lipoprotein particles that had markedly decreased cholesterol and apoE and had smaller apoE-containing particles than particles from Abca1 ؉/؉ astrocytes. These findings demonstrate that ABCA1 plays a critical role in CNS apoE metabolism. Since apoE isoforms and levels strongly influence Alzheimer's disease pathology and risk, these data suggest that ABCA1 may be a novel therapeutic target.

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Green tea (−)-epigallocatechin-gallate modulates early events in huntingtin misfolding and reduces toxicity in Huntington's disease models

et al. 2006

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Huntington's disease (HD) is a progressive neurodegenerative disorder for which only symptomatic treatments of limited effectiveness are available. Preventing early misfolding steps and thereby aggregation of the polyglutamine (polyQ)-containing protein huntingtin (htt) in neurons of patients may represent an attractive therapeutic strategy to postpone the onset and progression of HD. Here, we demonstrate that the green tea polyphenol (-)-epigallocatechin-3-gallate (EGCG) potently inhibits the aggregation of mutant htt exon 1 protein in a dose-dependent manner. Dot-blot assays and atomic force microscopy studies revealed that EGCG modulates misfolding and oligomerization of mutant htt exon 1 protein in vitro, indicating that it interferes with very early events in the aggregation process. Also, EGCG significantly reduced polyQ-mediated htt protein aggregation and cytotoxicity in an yeast model of HD. When EGCG was fed to transgenic HD flies overexpressing a pathogenic htt exon 1 protein, photoreceptor degeneration and motor function improved. These results indicate that modulators of htt exon 1 misfolding and oligomerization like EGCG are likely to reduce polyQ-mediated toxicity in vivo. Our studies may provide the basis for the development of a novel pharmacotherapy for HD and related polyQ disorders.

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